DE19605022A1 - Method for detecting an error on a line section to be monitored of an electrical transmission line according to the distance protection principle - Google Patents

Abstract

The invention concerns a method of detecting a fault in a monitored section of electric line, the method calling for a release signal and a direction signal to be generated, in the event of a fault, by a measuring unit fitted at each end of every section of line and for the direction signal to be transmitted via a low-transmission-capacity line to the other measuring unit in the section concerned. In order to be able to locate faults accurately, simply and inexpensively by a method of this kind, each measuring unit (13, 14) produces, following generation of the release signal, intermediate parameters (<u>I</u>, <u>U</u>) which are suitable for calculating the location of the fault and which are transmitted via the data-transmission line (21) to the other measuring unit (14, 13) in the section where, in each case, a value is obtained indicating the location of the fault.

Description

The invention relates to a method for detection an error on a line section to be monitored an electrical power transmission line according to Distance protection principle, in which each with a measuring arrangement at each end of the line section to be monitored current and voltage values of the energy transfer recorded there line in the event of an error on the line to be monitored tion section a trigger signal and a direction signal is witnessed and in which the directional signal via a between the data transmission line with the measuring arrangements low transmission capacity to the other measuring arrangement is transferred.

In a known method of this type (Siemens manual "7SA511 V3 digital branch protection", 1995, page 62) becomes reliable detection of an error on a monitor line section of an electrical energy transfer supply line at both ends of the line to be monitored cut according to the distance protection principle in the event of an error because it generates a trigger signal and thus an assigned Circuit breaker to separate the line section from the energy transmission line causes. Because from every end of the line section to be monitored with an error a method based on the distance protection principle only about 80% of the length of the line section to be monitored in Failure trap can be reliably detected at the be knew procedures at each end of the lei to be monitored direction section in the event of a fault, a direction signal with the Statement generates that the error towards the other its end lies; the direction signal is over a data transmission line to the other end or to each  transferred to another measuring arrangement. Because the direction signal is a simple binary signal or is transmitted serially, be a simple line is used as the data transmission line with low transmission capacity. With the respective receive NEN direction signal can take into account the because end self-generated direction signal with high Reliability an error on the Lei to be monitored tion section can also be recognized if the error in the respective end or start area of the Lei to be monitored tion section has occurred.

It is also from the German published application DT 21 12 136 an arrangement for monitoring a line cut an electrical transmission line known at each end of the line section to be monitored a distance protection arrangement is provided and also a Circuit arrangement for measuring the fault location distance having. The circuitry includes at each end of the line section to be monitored a memory in which after analog-digital conversion from the energy transmission line derived current and voltage values are saved the. In the event of an error on the Lei to be monitored The storage section becomes the values stored in the memory to an evaluation via a data transmission system direction transmitted by a computing system to determine the Location of the fault on the line section to be monitored is subordinate. The data transmission system must be from be comparatively high quality because of the relatively large amount of data must be transferred.

The invention has for its object a method for Detection of an error on a line to be monitored cut an electrical power transmission line ben, with whom not only the distance protection principle works Trigger signal can win, but in a simple manner a the location of the fault on the line to be monitored can produce the specified measured variable.  

In order to solve this problem, a method is used gangs specified type according to the invention in each measuring arrangement after the release of the trigger signal to calculate the error Suitable intermediate sizes provided locally and for each another measuring arrangement via the data transmission line averages; in each measuring arrangement, the own and the transmitted intermediate values indicating the location of the fault Measured variable obtained.

A major advantage of the method according to the invention is that there is no for the exact determination of the fault location additional data transmission system is needed, but to the for the transmission of the direction signals at the Di punch protection measurement used data transmission line back can be gripped; an additional - costly - data Transmission system for determining the fault location is not required. The data transmission line can cause errors location determination are used because after the Delivery of the direction signals or, after triggering, the Data transmission line is no longer needed and therefore can be used to determine the fault location. Allows this is due to the fact that according to the invention in the measuring arrangement Intermediate quantities are formed for the determination of the fault location those that are suitable for calculating the fault location. This Intermediate sizes can be via the data transmission line easily transmitted with low transmission capacity.

Different methods can be used in the method according to the invention Intermediate sizes are provided. It will be advantageous viewed if in each measuring arrangement one for the respective Fault location characteristic impedance as an intermediate size is provided. The measuring arrangement is namely at appropriate interpretation able from which only from the respective other measuring arrangement transmitted impedance variable to measure the fault location exactly. In itself, this type of mistake Location determination known from "IEE Proceedings", Vol, Part. C,  133 No. 6, September 1986, pages 359 to 368, in particular 363, known.

In another advantageous embodiment of the inventions The method according to the invention is in each measuring arrangement for the current and voltage characteristic of each fault location vectors provided as an intermediate size. The transfer too Such intermediate sizes are transferred via a data transfer Cable with low transmission capacity possible. On Such a method for determining the fault location is also for itself from "IEE Proceedings", Vol. 137, Part C, No. 6, No vember 1990, pages 395 to 402.

To explain the invention is in

Fig. 1 shows an embodiment of an arrangement for performing the method according to the invention, in

Fig. 2 shows another embodiment of an arrangement for performing the method according to the invention and in

Fig. 3 shows a block diagram for a more detailed explanation of the run of an embodiment of the inventive method shown.

In Fig. 1, an electric power transmission line 1 can be seen having a monitored line section 2; this line section 2 is delimited by a circuit breaker 3 at one end 4 of the line section 2 and by a further circuit breaker 5 at the other end 6 of the line section 2 to be monitored. About a in Fig. 1 only schematically shown current transformer 7 and a voltage converter 8 at the end 4 and a further current transformer 9 and another voltage converter 10 at the other end 6 of the line section 2 to be monitored, the currents and voltages of the energy transmission line 1 are corresponding Currents and voltages of an analog-digital converter arrangement 11 at one end 4 of the line section 2 and a further analog-digital converter arrangement 12 at the other end 6 are supplied. The analog-digital converter arrangements 11 and 12 each have a measuring arrangement 13 or 14 arranged in the form of a process computer.

The energy transmission line 1 is shown for the sake of clarity single-phase; in fact, it is three-phase, which is why a corresponding number of current and voltage transformers are provided in order to record the required measured variables.

In the measuring arrangements 13 and 14 from the digitized current and voltage values supplied to them in the event of an error, for example a short circuit, on the line section 2 to be monitored, a trigger signal is generated, by means of which a switch contact 15 or 16 each have one Switching device 17 or 18 is actuated. As a result, an actuation pulse is given to the circuit breaker 3 and 5 and causes it to open, whereby the line section 2 to be monitored is separated from the energy transmission line 1 . About further switching contacts 19 and 20 of the switching device 17 and 18 , a direction signal binary is transmitted from one measuring arrangement 13 to the other measuring arrangement 14 and from the other measuring arrangement 14 to a measuring arrangement 13 via a data transmission line 21 with low transmission capacity.

After a trigger signal has been generated by the measuring arrangements 13 and 14 , in the acquisition of which the directional signals exchanged via the data transmission line 21 have been taken into account, the data transmission line 21 is no longer required for error detection according to the distance protection principle. It is now used according to the inven tion for the binary transmission of intermediate quantities for fault location determination by the measuring arrangements 13 and 14 after the release of trigger signals provide these intermediate quantities for fault location determination. Since these intermediate quantities consist only of an impedance measurement quantity or an impedance vector or of current and voltage vectors, the data transmission line 21 can be used without any problems for the transmission of these intermediate quantities, so that the measuring arrangements 13 and 14 are now based on the above known methods for determining the fault location by means of the received intermediate quantities can carry out an exact fault location determination from both ends of the line section to be monitored and thus with high accuracy.

The embodiment of FIG. 2 is essentially the same as that of FIG. 1. The essential deviation of the embodiment of FIG. 2 from that of FIG. 1 is that a data transmission line 22 with low transmission capacity is used here as a serial transmission channel. The intermediate sizes required for determining the fault location are here exchanged serially between the measuring arrangements 13 and 14 via the data transmission line 22 .

The exemplary embodiment according to FIG. 3 serves - as already mentioned above - only to illustrate the process taking place in the measuring arrangements 13 and 14 ; the individual blocks of this figure are therefore not to be regarded as circuit units, but merely represent functional blocks. In FIG. 3, reference is also only made to the manner in which a measuring arrangement 13 or 14 is connected to one end of the line section to be monitored , because at the other end, the procedure is similar.

That a distance protection measurement by leading block 30 via a data bus 31 from the unillustrated analog-to-digital converter arrangement 11 and 12 of FIG. 1 output data is supplied to the FIG. 3 can be seen. In the case of a detected fault in the block 30 , not only an excitation signal is generated on the line section to be monitored and given via a connection 32 to a block 33 for determining the fault location, but also a direction signal 35 is transmitted to a block 34 for signal comparison.

The block 33 for determining the fault location is also located on the data bus 31 and generates current and voltage vectors I and U , which both reflect the state of the line section to be monitored before the occurrence of an error and during an error. The block 33 is connected via a connection 35 to a switching device 36 via which the data transmission line 21 according to FIG. 1 or 22 according to FIG. 2 can be connected to either the block 34 or the block 33 . The switching device 36 is normally switched so that the data transmission line 21 is connected to the block 34 via a connection 37 .

If, after excitation, a trip command has been issued by block 30 via an output 38 to a circuit breaker 3 or 5 , not shown, the circuit breaker 3 or 5 is open. The open state is detected by a detector 39 for detecting the opening state of the respective circuit breaker 3 or 5 and a corresponding signal is given to an input of a logic element 40 , to the further input of which a monitor 41 is connected to check the state of an automatic reclosing device . The logic gate 40 is followed by an AND gate 42 , which then gives a switching command to the switching device 36 via a connection 43 when both at the output of the logic element 40 and at an output 44 of the block 33 for determining the fault location Signal pending.

After switching the switching device 36 , the data transmission line 21 is connected directly to the block 33 via the connec tion 35 , so that an exchange of the intermediate sizes for fault location determination in the form of current and voltage vectors can take place. In block 33 , a measured variable that precisely specifies the location of the fault is obtained from the quantities recorded there and the intermediate quantities received.

Claims (3)

1. A method for detecting an error on a line section to be monitored of an electrical power transmission line according to the distance protection principle, in which

• - With a measuring arrangement at each end of the line section to be monitored with current and voltage values of the energy transmission line detected there, in the event of an error on the line section to be monitored, a trigger signal and a direction signal are generated and in which
  the direction signal is transmitted to the other measuring arrangement via a data transmission line running between the measuring arrangements and having a low transmission capacity, characterized in that
• - suitable intermediate variables ( I , U ) are provided in each measuring arrangement ( 13 , 14 ) after the trigger signal has been emitted for calculating the fault location,
• - The intermediate variables ( I , U ) to the other measuring arrangement (z. B. 14) are transmitted via the data transmission line ( 21 ) and
• - In each measuring arrangement ( 13 , 14 ) from the own and the transmitted intermediate values ( I , U ) a measured variable indicating the location of the fault is obtained.

2. The method according to claim 1, characterized in that

• - An impedance characteristic variable for the respective fault location is provided as an intermediate variable in each measuring arrangement.

3. The method according to claim 1, characterized in that

• - In each measuring arrangement ( 13 , 14 ) characteristic current and voltage vectors ( I , U ) for the respective fault location are provided as an intermediate variable.